Cavity-backed spiral antenna with perturbation elements

ABSTRACT

Satellites require a suitable antenna for line of sight microwave communication with the ground. Disclosed here is an Archimedean spiral antenna backed by a copper cavity containing quadruple conical perturbations. The antenna meets the required size, mass, transmitting power, bandwidth, and circular polarization for a satellite (e.g., CubeSat) environment while providing immunity to the mounting position.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority to and benefit of U.S. provisional patent application Ser. No. 62/613,640 filed Jan. 4, 2018, which is fully incorporated by reference and made a part hereof.

FIELD

The present disclosure relates to antennas and more specifically, to a cavity-backed spiral antenna for satellite applications that has perturbation elements within the cavity to improve performance.

BACKGROUND

Since the development of the first CubeSat in 1999, there have been great advancements in the design, construction, and deployment of amateur nano-satellites due to their simplicity and low cost. However, from 2000 to 2012, 47% of CubeSat failure was attributed to loss of contact [1], revealing the need for further development in communication and antenna systems.

CubeSat antenna development faces several challenges, including restrictions on size, mass, and transmitting power, while demanding wide bandwidth and circular polarization. Planar antennas have been designed as alternatives to the deployable monopole antennas common for small satellites, as they eliminate the possibility of mechanical failure and allow for low profile. Frequently-used planar antennas include slot and patch antennas, but these fail to achieve sufficient circular polarization bandwidth for satellite antennas [2].

In order to meet aforementioned antenna characteristics, other antenna designs have been proposed [15-18]. A patch antenna with metasurface [15] and a dipole antenna with artificial magnetic conductor (AMC) [16] are low profile and provide broadband. However, the patch antenna showed a narrow bandwidth of low axial ratio (AR) below 3 dB (3-dB AR bandwidth) at 1.45 GHz (23.4%) and 0.72 GHz (44.7%). A cavity-backed slot antenna showed a broader 3-dB AR bandwidth of 3 GHz (54.5%) [17], but the antenna gain fluctuated from 6 dBic to 9.9 dBic in the operating frequency. A cavity-backed spiral antenna array showed a similar 3-dB AR bandwidth and relatively stable antenna gain [18]. However, the antenna has a large area of 1.29λ_(L)×1.5λ_(L), where λ_(L) is the free space wavelength at the lowest frequency.

The spiral antenna is a good candidate for CubeSat satellite applications because it is frequency independent and characteristically circularly polarized [3]. A need, therefore, exists for an improved spiral antenna design to meet the requirements for communication in a CubeSat satellite application.

SUMMARY

Accordingly, disclosed herein is an antenna design to achieve broad bandwidth, high antenna gain, and circular polarization with low-profile. The antenna design embraces a cavity-backed Archimedean spiral antenna with quadruple conical perturbations (CBASA-QCP), which consists of an Archimedean spiral antenna (ASA) backed by a cavity having four conical perturbation elements (i.e., cones). The ASA typically has two radiator arms with a typical number of turns (n)=5, a typical radiator width (w)=0.7 mm, and a typical spacing (s)=1 mm. The ASA can be placed on a ROGERS DUROID™ 5880 substrate, which has a diameter of 40 millimeters (mm), a thickness of 0.787 mm, and a relative dielectric constant (ε_(r)) of 2.2. The backing cavity typically consists of four conical perturbations with a possible cone height (h_(cone))=2 mm and cone diameter (D_(cone))=8 mm for a cavity height (h_(cav))=6 mm. This antenna design allows for a wide −10-dB impedance bandwidth (e.g., of greater than 124.3% over 7-30 GHz), 3-dB axial ratio bandwidth (e.g., of 107.2% over 8-26.5 GHz), 3-dB gain bandwidth (e.g., of 72% over 7-15 GHz and of 28.6% over 19.7-26.5 GHz), and a high peak realized gain (RG) (e.g., of 10.7 dBic) at boresight.

Thus, in one aspect, the present disclosure embraces an antenna, consisting of an antenna element having two conductive arms disposed on a circular substrate wherein each conductive arm begins at one side of a feed port and traces a spiral for a plurality of revolutions. The antenna also includes a cylindrical cavity comprising a cavity base and a cavity wall, wherein the cavity wall defines an opening that substantially matches a diameter of the circular substrate. The cylindrical cavity is positioned behind the antenna element so that the substrate covers the opening formed by the cavity wall. One or more perturbation elements are disposed or formed on the cavity base. Each perturbation element has an element base that is flush with the cavity base and an element top at a height above the cavity base. The height of each element top is between the cavity base and the circular substrate.

In an example embodiment of the antenna, the spiral is an Archimedean spiral.

In another example embodiment of the antenna, each perturbation element is a cone, a cylinder, or a cone with a flat top. In these embodiments, aspects of the antenna's performance may be affected by a shape, a size, a number and/or an arrangement of the perturbation elements. For example, the performance affected may include a bandwidth, an axial ratio, or a gain measured at the feed point of the antenna.

In another example embodiment of the antenna, each conductive arm may be a conducting polymer, metal, or metal alloy.

The foregoing illustrative summary, as well as other exemplary objectives and/or advantages of the disclosure, and the manner in which the same are accomplished, are further explained within the following detailed description and its accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A illustrates a perspective view of an orbital path of a satellite.

FIG. 1B is a schematic view of a satellite communication link scenario.

FIG. 2 depicts a top perspective view of a Archimedean spiral antenna according to an implementation of the present disclosure.

FIG. 3A is a graph showing reflection coefficients, axial ratios, and realized gain for a range of frequencies of the Archimedean spiral antenna of FIG. 2.

FIG. 3B is a polar plot showing the antenna pattern of the Archimedean spiral antenna of FIG. 2.

FIG. 4A depicts a perspective section view of a cavity backed Archimedean spiral antenna without perturbation elements according to prior art.

FIG. 4B depicts a perspective section view of a cavity backed spiral antenna with one perturbation element according to an implementation of the present disclosure.

FIG. 4C depicts a perspective section view of a cavity backed spiral antenna with a plurality of perturbation elements according to an implementation of the present disclosure.

FIG. 5A is a graph showing simulated reflection coefficient versus frequency for no perturbation elements, one perturbation element, and four perturbation elements as compared to a requirement (dotted line).

FIG. 5B is a graph showing axial ratio (left vertical axis) and realized gain (right vertical axis) for a range of frequencies and for the antennas with no perturbation elements, one perturbation element, and four perturbation elements.

FIG. 6 is a graph showing axial ratio (left vertical axis) and realized gain (right vertical axis) for a range of frequencies and for different perturbation element heights.

FIG. 7A is a top plan view of a cylindrical cavity having four conical perturbation elements according to an implementation of the present disclosure.

FIG. 7B is a top plan view of an antenna element according to an implementation of the present disclosure.

FIG. 7C is a is a top plan view of feed circuit for coupling a coaxial transmission line to a feed port of the antenna element of FIG. 7B according to an implementation of the present disclosure.

FIG. 8 is a side view a cavity-backed Archimedean spiral antenna with quadruple conical perturbations (CBASA-QCP) mounted on a 3U cube satellite (CubeSat) frame according to an implementation of the present disclosure.

FIG. 9A is a graph of simulated and measured reflection coefficients of the CBASA-QCP for a range of frequencies according to an implementation of the present disclosure.

FIG. 9B is a graph of simulated and measured axial ratios of the CBASA-QCP for a range of frequencies according to an implementation of the present disclosure.

FIG. 9C is a graph of simulated and measured realized gain and radiation efficiency of the CBASA-QCP for a range of frequencies according to an implementation of the present disclosure.

FIG. 10A is a polar plot showing the antenna pattern of the CBASA-QCP at 8 gigahertz (GHz) according to an implementation of the present disclosure.

FIG. 10B is a polar plot showing the antenna pattern of the CBASA-QCP at 11.2 GHz according to an implementation of the present disclosure.

FIG. 11 are plots showing the simulated frequency dependent reflection coefficient (Γ), axial ratio at boresight (AR₀₀), and realized gain at boresight (RG₀₀) for an optimized CBASA-QCP according to an embodiment of the present disclosure.

FIG. 12A is a side view of the CBASA-QCP illustrating a range of antenna locations with respect to the frame according to implementations of the present disclosure.

FIG. 12B is a perspective view of a 1U CubeSat mock-up for testing the CBASA-QCP according to an implementation of the present disclosure.

FIG. 13A is a graph of simulated and measured axial ratios of the CBASA-QCP for a range of frequencies at three antenna locations.

FIG. 13B is a graph of simulated and measured realized gain of the CBASA-QCP for a range of frequencies at three antenna locations.

DETAILED DESCRIPTION Link Scenario

The design of the antenna requires a knowledge of the link and power budges for communication in the satellite (e.g., CubeSat) environment. Accordingly, a link scenario is first determined.

The purpose of the link scenario is to accurately depict all visible encounters between the satellite and ground station for the CubeSat's orbit around the earth. Using NASA's open-source General Mission Analysis Tool (GMAT) [4], a circular Low Earth Orbit (LEO) was simulated at altitude of 400 km with a semi-major axis of 6771 km, an eccentricity of approximately 0, an inclination of 51.3°, and a longitude of ascending node of 170.1347°, as shown in FIG. 1A and FIG. 1B. The ground station was chosen to be located in Tuscaloosa, Ala., U.S.A with an elevation of 0 km. The following equations were used to determine the average velocity (v_(orbit)) and period (T) of the CubeSat in orbit [5]:

${v_{orbit} = \sqrt{G \cdot {M/r_{s}}}},{T = {2\pi{\sqrt[3]{r_{s}^{2}}/\sqrt{G \cdot M}}}},$ where G is the gravitational constant, M is the mass of Earth, and r_(s) is the distance from the center of the Earth to the satellite. The standard mass of the CubeSat (3 kg) was used. From these calculations, v_(orbit) is 7.676 km/s and T is 5541 seconds, meaning the CubeSat completes 15.59 orbits per day.

The satellite communication link requires Line-of-Sight (LoS) communication. Therefore, visibility calculations were performed using the following trigonometric equations [6]: d=r _(s)√{square root over (1+(r _(e) /r _(s))²−2(r _(e) /r _(s))cos(γ))}, γ≤cos⁻¹(r _(e) /r _(s)), where d is the distance between the satellite and ground station, γ is the angle between the satellite sub-point and ground station, r_(e) is the radius of the earth. With a minimum elevation of 20°, γ is limited to a maximum of 6.55°, which allows us to determine the maximum d using above equations. Using the simulation of the CubeSat's orbit, the range d was found over a period of 24 hours and the minimum d was determined. Therefore, LoS communication is constrained to d values between 433 km and 1,000 km.

Required Antenna Performance

A satellite link budget accounts for propagation losses in addition to losses caused by polarization mismatch [7, 9]. The basic link budget can be calculated using the Friis equation:

$\frac{P_{r}}{P_{t}} = {G_{t}{G_{r}\left( \frac{\lambda}{4\pi\; d} \right)}^{2}\left( {1 - {\Gamma_{t}}^{2}} \right)\left( {1 - {\Gamma_{r}}^{2}} \right){{a_{t} \cdot a_{r}^{*}}}^{2}}$ where P_(r) is the receiving antenna power, P_(t) is the transmitting antenna power, G_(t) is the transmitting antenna gain, G_(r) is the receiving antenna gain, d is the distance between the receiving and transmitting antennas, λ is the wavelength of the target frequency, Γ_(t) is the reflection coefficient of the transmitting antenna, Γ_(r) is the reflection coefficient of the receiving

TABLE I LINK BUDGET FOR A CUBESAT ANTENNA 8 GHz 11.2 GHz (X-band) (Ku-band) Input Parameters Transmitting power (Satellite) 37 dBm 37 dBm Max. communication path distance 1,000 km 1,000 km Receiving power (Ground) [7] −90 dBm −90 dBm Receiving antenna gain (Ground) [8] 36.5 dBi 41.5 dBi Output Parameters Path loss 170.51 dB 173.42 dB Min. transmitting antenna gain 7.02 dBi 4.94 dBi (Satellite) antenna, and a_(t) and a_(r) are the polarization vectors of the transmitting and receiving antennas, respectively [3]. The calculated link budget is summarized in Table I.

The parameters for the ground station antenna can be estimated from a commercially available ground station antenna [8] and used to calculate the link budget.

According to the link budget estimation at the maximum communication distance of 1,000 kilometer (km), the antenna must have a gain of 7.02 decibels relative to isotropic (dBi) and 4.94 dBi at 8 GHz and 11.2 GHz, respectively. Note that additional losses will be introduced by polarization mismatch, atmospheric effects during propagation, and insertion loss from the feeding, which were not taken into consideration in the link budget calculation. However, the link budget has been calculated for upper limit of the range of path distances, 433 to 1000 km, which allows for a loss margin of 7 dB.

Antenna Design and Simulation

From the link and power budget calculations, the CubeSat antenna must achieve a minimum gain of 7 dBi and 5 dBi at 8 GHz and 11.2 GHz, respectively, to cover a wide communication distance up to 1,000 km with high efficiency for efficient power management. In addition, a circularly polarized antenna is favorable for satellite wireless communication because circular polarization eliminates the adverse effects of using a linearly polarized antenna, which include a 3 decibel (dB) loss from Faraday rotation and additional losses from polarization mismatch [2, 9]. Also, wide bandwidth is favorable for the CubeSat applications. To meet these requirements, an Archimedean spiral antenna (ASA) backed by a copper cavity containing conical perturbations is disclosed. A balun is also disclosed for converting unbalanced to balanced input signals and transforming impedance from a coaxial transmission line to the a feed port of the spiral antenna element.

In what follows, example embodiments of the disclosure (and their simulation and measured performance) will be described. Those skilled in the art will also appreciate that various adaptations and modifications of the preferred and alternative embodiments described can be configured without departing from the scope and spirit of the disclosure. Therefore, it is to be understood that, within the scope of the appended claims, the disclosure may be practiced other than as specifically described.

Archimedean Spiral Antenna and Balun

The ASA has a planar structure and characteristically wide bandwidth with respect to both circular polarization and impedance [3, 10]. An ASA consists of two conductive radiator arms (i.e., arms) with a number of turns (n) of 5, an arm width (w) of 0.7 millimeters (mm), and a spacing (s) of 1 mm. The conductive arms are disposed on a circular substrate of ROGERS DUROID™ 5880. As shown in FIG. 2, the circular substrate has a diameter of 40 mm, a thickness of 0.787 mm. The substrate of ROGERS DUROID™ 5880 has a relative dielectric constant (ε_(r)) of 2.2.

As shown in FIG. 3A, the ASA shows a good impedance matching with wide bandwidth, and low axial ratio at boresight (AR₀₀: <3 dB) above 3.5 GHz. Also as shown in FIG. 3A, the realized gains at boresight (RG₀₀) of the ASA are 5.2 dBi at 8 GHz and 6 dBi at 11.2 GHz, which do not meet the minimum required gain. In addition, the radiation pattern of the ASA in FIG. 3B is bidirectional, resulting in the loss of half of the antenna's power. Additionally, fixing the ASA directly to the face of the CubeSat would negate the desirable ASA qualities due to ground plane effects [4]. Lastly, if left unshielded, adjacent electronic systems may experience electromagnetic interference (EMI). In order to address the aforementioned issues, the ASA can be backed by a cylindrical cavity, which will be discussed in the next section.

A tapered microstrip balun is used to feed ASA (see FIG. 7C). The balun uses a Klopfenstein taper [11-13] to transform the impedance from 50 ohms (Ω) to 150Ω and convert an unbalanced signal to a balanced signal. Simulated balun performance shows a wide operation frequency range with low insertion loss (IL=−20 log|S21|).

Cylindrical Cavity with Perturbation Elements

In order to alleviate issues for the ASA discussed in the previous section, a backing cavity was designed to improve realized gain (RG) and reflect the back radiation. Three backing cavities were designed and simulated with the optimized ASA. As shown in FIGS. 4A, 4B, and 4C, the variations include a conventional cylindrical back cavity with no perturbation elements (i.e., NP cavity) (FIG. 4A), a cavity with a center single conical perturbation element (i.e., SCP cavity) (FIG. 4B), and a cavity with quadruple (4) conical perturbation elements (QCP cavity) (FIG. 4C).

A conventional cavity-backed Archimedean spiral antenna (CBASA) with no perturbation (NP) elements is shown in FIG. 4A, while FIGS. 4B and 4C illustrate the CBASA of FIG. 4A with a single conical perturbation (SCP) element and quadruple conical perturbation (QCP) elements respectively. As show, a cavity height (h_(cav)) of 12 mm and a diameter (D_(cav)) of 40 mm are chosen for each CBASA variation. The conical perturbation element diameters (D_(cone)) of 20 mm and 8 mm are chosen for the SCP and QCP cavities, respectively, and a conical perturbation element height (h_(cone)) of 7 mm is chosen for both SCP and QCP cavities.

All three variations of cavities (i.e., NP, SCP, and QCP) have good frequency independent characteristics when placed behind the ASA in simulation. FIGS. 5A-5B show the simulated antenna performance of CBASA with NP, SCP, and QCP. As shown in FIG. 5A, all three antennas show a good impedance matching (reflection coefficient (Γ)<−10 dB) over the frequency range from 7 GHz to 12 GHz, indicating frequency independent characteristics. FIG. 5B shows antenna radiation performance. The CBASA with NP cavity has a large drop in realized gain at boresight (RG₀₀) at 9.5 GHz, which persists past 12 GHz. This disruption of wideband behavior is caused by excitation of cavity modes [19]. To improve wideband characteristics, absorbing materials have been inserted into cavities [14, 20], which results in reduction of the antenna gain [19, 21]. Alternatively, to maintain antenna gain, perturbations have been added to backing cavities to reduce gain variations [19]. By introducing SCP, the RG₀₀ drop still appears at 9.5 GHz. However, the RG₀₀ was restored to about 7 dBi above 11 GHz. By employing QCP cavity, the RG₀₀ drop frequency shifts to a lower frequency. Furthermore, the RG₀₀ for the cavity backed ASA with QCP cavity (CBASA-QCP) is nearly restored up to 7 dBi above 9.2 GHz. However, the axial ratio at boresight (AR₀₀) for the CBASA-QCP shows a peak at the dip of RG₀₀ (8.7 GHz), which limits the operational bandwidth.

To address the above issues, the QCP cavity design was optimized by varying h_(cone). It is clearly observed that the RG₀₀ drop shifted to a lower frequency as h_(cone) increased from 3 mm to 11 mm, as shown in FIG. 6. Also, the unwanted peak in AR₀₀ is shifted to a lower frequency. Accordingly, the h_(cone) of 11 mm and diameter of 8 mm resulted in the AR₀₀ below 3 dB and RG₀₀ above 7.5 dBi for the entire range from 8 GHz to 12 GHz, which allows wide operation bandwidth. The design parameters used in a fabrication of the QCP cavity was as follows: h_(cone) of 11 mm and D_(cone) of 8 mm.

Antenna Fabrication and Measurement

The ASA and balun may be milled on Rogers Duroid 5880 using an LPKF S62™ Milling Machine. The backing cavities can be fabricated from copper C101 oxygen free stock. The balun extends into a parallel plate transmission line, which passes through a 2.5 mm hole in the bottom of the cavity to connect to the fabricated spiral antenna. FIGS. 7A-7C show the fabricated QCP cavity (FIG. 7A), ASA (FIG. 7B), and a tapered microstrip balun (FIG. 7C). Also, a side view of the fabricated antenna mounted on the small (10 cm×10 cm) face of the 3U CubeSat is shown in FIG. 8.

The tapered microstrip balun feeds the CBASA and converts unbalanced input signals to balanced input signals. The balun also transforms the impedance from 50 ohms (Ω) to 150Ω. When assembled, the tapered microstrip balun passes through a 2.5 mm hole in the bottom of the QCP cavity to connect to the ASA.

To test the balun, a double ended balun was fabricated which transforms the impedance from 50 ohms (Ω) to 150Ω then back to 50Ω. A Vector Network Analyzer (VNA: AGILENT™ N5320A) was used to measure the S₁₁ and S₂₁. The fabricated balun showed a low reflection coefficient (Γ) and insertion loss (IL) at X-band. However, measured behaviors of the Γ and IL were slightly degraded at high frequencies (f>10 GHz), which was different from the simulated results. This small discrepancy occurred due to fabrication errors.

The Γ of the fabricated CBASA-QCP is shown in FIG. 9A. Sufficient impedance matching was achieved from 7.5 GHz to 12 GHz, which can include X-bands and Ku-bands. However, a slight difference between the measured and simulated Γ is observed due to imperfections in fabrication of the balun. The radiation characteristics of the fabricated antenna, which include the frequency dependent RG₀₀ and the radiation pattern, were measured in the frequency range from 7 GHz to 10 GHz using the Anechoic Chamber (e.g., RAYMOND EMC QUIETBOX AVS™ 700). The measured AR₀₀ (FIG. 9B) and RG₀₀ (FIG. 9C) follow the trends of the simulated AR₀₀ (FIG. 9B) and RG₀₀ (FIG. 9C). At 8 GHz, the measured AR₀₀ is below 3 dB and the RG₀₀ is 7 dBi, which meet the requirements of the specifications of the CubeSat antenna. Moreover, the simulated RE of the antenna is higher than 95% in the frequency above 7.5 GHz (FIG. 9C), which is essential for efficient power management.

In FIGS. 10A and 10B, the simulated radiation patterns at 8 GHz (FIG. 10A) and 11.2 GHz (FIG. 10B) reveal the effect of the backing cavity as it redirects the back-lobe and increases the RG₀₀. This behavior is confirmed by the measured radiation pattern at 8 GHz. It is also noted that the simulated (co-pol: E_(RHCP)) and measured (co-pol: E_(LHCP)) polarizations are not matched. This is because the top side of the ASA of the fabricated CBASA-QCP, which has the spiral radiator, was flipped, as compared to that of the simulated CBASA-QCP, in order to be fed by the balun.

Further improvement in −10-dB impedance bandwidth, 3-dB AR bandwidth, and 3-dB gain bandwidth was achieved by optimizing H_(cav), H_(cone), and D_(cone). FIG. 11 shows the simulated antenna performance of optimized CBASA-QCP with H_(cav) of 6 mm, H_(cone) of 2 mm, and D_(cone) of 8 mm. An optimized CBASA-QCP shows a −10-dB impedance bandwidth of 23 GHz (7-30 GHz), 3-dB AR bandwidth of 18.5 GHz (8-26.5 GHz), and 3-dB gain bandwidth of 8 GHz (7-15 GHz).

Antenna performance of the optimized CBASA-QCP was compared with the reported wideband circularly polarized antennas [15-18] and is summarized in Table II.

TABLE II ANTENNA PERFORMANCE COMPARISON OF WIDEBAND CIRCULARLY POLARIZED ANTENNAS. −10-dB 3-dB Axial Impedance Ratio 3-dB Gain Peak Area Bandwidth Bandwidth Bandwidth Gain [15] 0.27 λ_(L) ² 45.6% 23.4%  >36% 7.6 dBic (0.52 λ_(L) × 0.52 λ_(L)) [16] — 66.3% 44.7% 48.2% 6 dBic [17] 1.1 λ_(L) ² 92.1% 54.5%   50% 9.9 dBic (1.05 λ_(L) × 1.05 λ_(L)) [18] 1.934 λ_(L) ² 64.3% 54.3% >66.7%  10.84 dBic (1.29 λ_(L) × 1.5 λ_(L)) Invented 0.89 λ_(L) ² >124.3%  107.2%    72% 10.7 dBic CBASA- (D = 1.07 λ_(L)) (7-30 GHz) (8-26.5 GHz) (7-15 GHz)/ QCP 28.6% (19.7-26.5 GHz) λ_(L) is the air wavelength at lowest frequency.

The disclosed CBASA-QCP has a −10-dB impedance bandwidth of 124.3%, 3-dB AR bandwidth of 107.2%, and 3-dB gain bandwidth of 72% and 28.6% with high peak gain of 10.7 dBic. These are much higher than those of recently developed antennas [15-18]. Accordingly, the disclosed CBASA-QCP can simultaneously cover operation frequencies of X-band (8-12 GHz), Ku-band (12-18 GHz), and K-band (18-27 GHz) with a small area of 0.89λ_(L) ², where λ_(L) is the free space wavelength at the lowest frequency. The CBASA-QCP is suitable for small satellite applications.

Antenna Placement on the 3U CubeSat

Simulation and measurement were performed to investigate the effect of an aluminum (Al) body of a 3U CubeSat on antenna performance. Accordingly, the optimal placement of the antenna by varying the location of the cavity (Loc_(Z): distance between the bottom of the antenna cavity and the face of the CubeSat) was determined as shown in FIG. 12A. For measurement, a 1U CubeSat mock-up (dimension: 10 cm×10 cm×10 cm) was made, and the fabricated antenna was loaded onto the mock-up, which is shown in FIG. 12B (b). FIGS. 13A and 13B show the simulated and measured AR₀₀ and RG₀₀ of the CBASA-QCP with different Loc_(Z). The simulated AR₀₀ is close to 3 dB at 8 and 11.2 GHz for all Loc_(Z), although the measured data reveals that it is slightly higher than 3 dB for Loc_(Z) of −6 and −12 mm. Moreover, decreasing Loc_(Z) from 0 to −12 mm increases the measured RG00 from 7.1 to 7.9 dBi. Therefore, it is confirmed that the CBASA-QCP can be loaded onto the CubeSat with good radiation performance.

CONCLUSION

An antenna with circular polarization, high radiation efficiency (RE), and high gain of 7.02 dBi and 7.9 dBi at 8 GHz and 11.2 GHz, respectively is disclosed. The cavity design allows for a low axial ratio (<3 dB) and high peak realized gain (>6.7 dBic) at boresight in the frequency range from 8 GHz to 12 GHz. A uni-directional radiation pattern was achieved with the invented cavity-backed Archimedean spiral antenna with quadruple conical perturbations (CBASA-QCP). Therefore, electromagnetic interference with internal electronics can be reduced.

The antenna meets the requirements of circular polarization, high radiation efficiency (RE), and high gain (i.e., 7.02 dBi and 4.94 dBi at 8 GHz and 11.2 GHz, respectively), which matches the determined link and power budgets for a calculated link scenario.

The antenna is a cavity-backed Archimedean spiral antenna with quadruple conical perturbations (CBASA-QCP). The antenna shows an axial ratio at boresight of less than 3 dB for most of the frequency range from 8 GHz to 12 GHz. Also, the antenna has a uni-directional radiation pattern at 8 GHz. The realized gain of the antenna at boresight (RG₀₀) is stabilized over the whole frequency range by introducing a QCP cavity. The simulated and measured RG₀₀ of the antenna are 8.2 dBi and 6.9 dBi at 8 GHz, and the simulated RG₀₀ of the antenna is 7.9 dBi at 11.2 GHz. Therefore, the requirements of the link budget are met. In addition, the simulated RE is stabilized at 95% from 7.5 GHz to 12 GHz. Lastly, the antenna is unaffected by mounting location on the CubeSat mock-up. Therefore, the developed CBASA-QCP is suitable for satellite-ground wireless communication, especially for small satellites.

The antenna is further improved in −10-dB impedance bandwidth (>124.3%: 7-30 GHz), 3 dB-dB axial ratio bandwidth (107.2%: 8-26.5 GHz), and 3-dB gain bandwidth (72%: 7-15 GHz and 28.6%: 19.7-26.5 GHz) by optimizing the cavity with quadruple conical perturbations (QCP cavity).

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art. Methods and materials similar or equivalent to those described herein can be used in the practice or testing of the present disclosure. As used in the specification, and in the appended claims, the singular forms “a,” “an,” “the” include plural referents unless the context clearly dictates otherwise. The term “comprising” and variations thereof as used herein is used synonymously with the term “including” and variations thereof and are open, non-limiting terms. The terms “optional” or “optionally” used herein mean that the subsequently described feature, event or circumstance may or may not occur, and that the description includes instances where said feature, event or circumstance occurs and instances where it does not. Ranges may be expressed herein as from “about” one particular value, and/or to “about” another particular value. When such a range is expressed, an aspect includes from the one particular value and/or to the other particular value. Similarly, when values are expressed as approximations, by use of the antecedent “about,” it will be understood that the particular value forms another aspect. It will be further understood that the endpoints of each of the ranges are significant both in relation to the other endpoint, and independently of the other endpoint.

REFERENCES

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The invention claimed is:
 1. An antenna, comprising an antenna element comprising two conductive arms disposed on a circular substrate, wherein each conductive arm begins at one side of a feed port and traces a spiral for a plurality of revolutions, wherein each arm has an arm width (w) of 0.7 millimeters (mm), and a spacing (s) of 1 mm; a cylindrical cavity comprising a cavity base and a cavity wall, wherein the cavity wall defines an opening that substantially matches an outer diameter of the circular substrate, and wherein the cylindrical cavity is positioned behind the antenna element so that the substrate covers the opening formed by the cavity wall to form an airspace enclosed by the circular substrate, cavity wall, and cavity base; and a plurality of conical perturbation elements disposed or formed on the cavity base within a diameter defined by an outermost boundary of the spiral of the conductive arms, wherein each perturbation element extends from the cavity base in an axial direction toward the circular substrate, each perturbation element having has an element base that is flush with the cavity base, said element base having a diameter and an element top at a height above the cavity base, and wherein the height of each element top is in the airspace between the cavity base and the circular substrate, wherein the cavity has a height (H_(cav)), each conical perturbation element has a base diameter (D_(cone)) and a height (H_(cone)), wherein H_(cav), D_(cone) and H_(cone) are configured such that the antenna has a −10-dB impedance bandwidth a 124.3% or greater at 7-30 GHz measured at the feed port, a 3 dB axial ratio bandwidth of 107.2% at 8-26.5 GHz measured at the feed port, and a 3-dB gain bandwidth of 72% at 7-15 GHz and 28.6% at 19.7-26.5 GHz measured at the feed port, and wherein said cavity base defines a hole, said hole for connecting a balun with the feed port, wherein said hole does not interfere with any one of the plurality of conical perturbation elements.
 2. The antenna according to claim 1, wherein the spiral is an Archimedean spiral and the plurality of revolutions is five.
 3. The antenna according to claim 1, wherein the −10-dB impedance bandwidth measured at the feed port of the antenna depends at least in part on a size, a number and/or an arrangement of the perturbation elements.
 4. The antenna according to claim 1, wherein the 3 dB axial ratio bandwidth measured at the feed port of the antenna depends at least in part on a size, a number and/or an arrangement of the perturbation elements.
 5. The antenna according to claim 1, wherein the 3-dB gain bandwidth measured at the feed port of the antenna depends at least in part on a size, a number and/or an arrangement of the perturbation elements.
 6. The antenna according to claim 1, wherein each conductive arm is a conducting polymer, metal, or metal alloy.
 7. The antenna according to claim 1, wherein the plurality of conical perturbation elements comprise quadruple conical perturbations.
 8. The antenna according to claim 7, wherein H_(cone) of each of the quadruple conical perturbations is 11 mm and D_(cone) of each of the quadruple conical perturbations is 8 mm.
 9. The antenna according to claim 8, wherein the antenna has an axial ratio (AR) below 3 dB and a realized gain (RG) above 7.5 dBi for a frequency range from 8 GHz to 12 GHz.
 10. The antenna according to claim 1, wherein the cavity is comprised of copper. 